JP3595778B2 - Base station apparatus and channel allocation method - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a base station device and a channel assignment method used in a wireless communication system that performs channel segregation.
[0002]
[Prior art]
An example of a conventional channel allocation method is described in a document (Channel Segmentation a Distributed Adaptive Channel Allocation Scheme for Mobile Communication Systems, IEICE TRANSACTIONS, 74N. FIG. 25 is a flowchart generated from this document.
[0003]
First, the base station device defines a priority function Pi (i is a channel number) for each channel (wireless resource). In this state, when a call is generated, a channel having the "highest priority function" and not "busy (busy)" is set for observation, and the interference wave power of the channel is measured (ST1: step 1).
[0004]
Then, it is determined whether or not the interference wave power is larger than a predetermined threshold (ST2). In this determination, if the interference wave power is larger than the predetermined threshold, the channel is set to "busy" (ST3). On the other hand, if the interference wave power is equal to or less than the predetermined threshold, the channel is set to "idle (idle)" (ST4).
[0005]
If the channel is "idle", the base station apparatus starts communication using the channel and increases the priority function of the channel (ST5). On the other hand, if the channel is “busy”, the base station device lowers the priority function of the channel (ST6). Then, the channel with the next highest priority function is set for observation, and the process returns to ST1 (ST7). When all the channels are "busy", it is determined that a call is lost.
[0006]
In this way, by managing the priority function for each channel, a channel having a higher priority function (possibility of use) at a certain base station naturally has a lower priority function at another peripheral base station. . Such an algorithm is called “channel segregation”.
[0007]
[Problems to be solved by the invention]
However, in the channel segregation, since the order of the channel search is determined only by the past history information, there is a problem that the information at the time of performing the channel search is not used. Specifically, it is assumed that a certain channel is frequently used and the priority table is high. However, when the same channel is used in another cell when the use of the channel is low, if the same channel is used in another cell, the measurement is repeated whether or not the channel can be used according to the priority table even though the interference is large and the allocation cannot be performed. Become.
[0008]
Further, in the above-described conventional channel allocation method, the priority table is updated only when there is a call connection request. Therefore, unless the call connection request occurs for a long time, the contents of the priority table are not updated during that time. . Further, in the above-described conventional channel allocation method, when a channel that can be allocated is searched, the priority function is not updated for a channel having a lower priority function than the channel. If the contents of the priority table are not updated for a long time and the slot assignment state of another cell changes during that time, channel assignment is performed based on the contents of the priority table that does not reflect the current line quality. Will be lost.
[0009]
The present invention has been made in view of the above points, and can promote channel segregation and perform efficient channel search, and can perform channel assignment based on the contents of a priority table reflecting current line quality. It is an object of the present invention to provide a base station apparatus and a channel assignment method that can be used.
[0010]
[Means for Solving the Problems]
The base station device of the present invention Storage means for storing an uplink / downlink priority function for all channels, and channel assignment based on the uplink / downlink priority function, and the same channel priority of the downlink at the time of uplink channel assignment Update the function, and update the same channel priority function of the uplink when the downlink channel is allocated Channel assignment means The channel allocating means decreases the priority function of the same channel on the reverse channel of the channel whose priority function has been raised, and raises the priority function of the same channel on the reverse channel of the channel whose priority function has been lowered. Take the configuration.
[0024]
this With the configuration, the priority function of a line to which no channel is allocated can be updated, so that when the upper and lower lines are switched, the channel can be allocated based on the contents of the priority table reflecting the current line quality. It is possible to prevent unnecessary channel search.
[0025]
The base station apparatus according to the present invention employs a configuration in which the channel allocating unit sets the priority function of the switched channel to a predetermined value when switching the uplink and downlink of the channel.
[0026]
With this configuration, it is possible to suppress the priority function of the channel for which the uplink and downlink have been switched, so that it is possible to prevent sudden switching between the uplink and downlink.
[0027]
The base station apparatus of the present invention employs a configuration in which the channel allocating unit updates the priority function based on the magnitude relationship between the desired wave power and the interference wave power.
[0028]
The base station apparatus of the present invention employs a configuration in which the channel allocating unit lowers the priority function when the fluctuation of the desired wave power is small and the interference wave power is increasing.
[0029]
With these configurations, the interference signal increases due to the start of communication of another base station or mobile station, and even when handover needs to be performed, the priority of a channel that is susceptible to interference can be lowered. Handover opportunities can be reduced.
[0036]
The base station device of the present invention What is claimed is: 1. A base station device for performing wireless communication by a CDMA / TDD communication method, comprising: storage means for storing a priority function of each slot; and slot selection for selecting a slot to be searched based on the priority function of each slot. Means, and channel assignment means for performing channel assignment based on the channel quality estimation value of the selected slot and updating the priority function, The channel allocating means adopts a configuration in which the priority function of a slot whose number of multiplexed codes is equal to or less than a threshold is lowered, and the priority function of a slot whose number of multiplexed codes is larger than the threshold is increased.
[0037]
this According to the configuration, channel search can be performed from a slot having a large number of code multiplexes at the time of channel assignment, so that a state of code pooling can be maintained.
[0038]
The base station apparatus according to the present invention is a base station apparatus that performs wireless communication using the CDMA / TDD communication method, and includes a storage unit that stores a threshold value for each transmission rate and a priority function of each slot for each transmission rate. There was a request Call Transmission rate priority function In descending order Slot selection means for selecting a slot to be searched, and reception interference power of the selected slot Allocates a channel to the slot when the connection rate is equal to or less than the threshold of the transmission rate of the call for which the connection request has been made. A configuration including channel assignment means is adopted.
[0041]
this According to the configuration, a threshold can be set for each transmission rate, and a channel search can be performed by selecting a slot in descending order of the priority function among desired transmission rates, so that a channel search can be performed. In this case, channel segregation can be performed efficiently.
[0042]
The base station apparatus of the present invention employs a configuration in which the channel allocation means increases the priority function of the slot to which the channel has been allocated.
[0043]
The base station apparatus of the present invention employs a configuration in which the channel allocating means reduces the priority function of the slot when the received interference power of the search target slot is larger than a threshold.
[0044]
With these configurations, the priority function can be updated based on the result of the channel search, so that efficient channel allocation can be performed.
[0045]
The base station apparatus according to the present invention is a base station apparatus that performs wireless communication by a CDMA / TDD communication method, and includes a storage unit that stores a priority function and a code multiplex number of each slot; Select the slot to be searched from among the slots with the largest number of code multiplexes among the selection candidate slots that have not yet been selected as the search target Slot selection means and reception interference power of the selected slot Assign a channel to the slot if is less than or equal to the threshold A configuration including channel assignment means is adopted.
[0047]
The base station apparatus according to the present invention employs a configuration in which the slot selection means selects, as a search target, a slot having the highest priority function among selection candidate slots having the largest number of code multiplexes.
[0048]
According to these configurations, channel search can be performed in the order of the priority function in the slot having the largest number of code multiplexes, so that channel segregation that naturally becomes code pooling in the CDMA / TDD communication system can be performed. .
[0049]
Further, a slot having a large number of code multiplexes has a low possibility of being used for communication in a peripheral base station and has a high possibility that the reception interference power is equal to or lower than a threshold value. As a result, it is possible to shorten the time until a slot is allocated and to reduce the amount of calculation.
[0050]
The base station device of the present invention A base station device for performing wireless communication by a CDMA / TDD communication method, wherein a storage unit stores a priority function and a code multiplex number of each slot; Selection rank calculating means for calculating a selection rank function using the priority function of each slot and the number of multiplexed codes of each slot as parameters When, The slot having the highest selection order function among slots not yet selected as a search target is selected as a search target. A slot selecting unit; and a channel allocating unit for allocating a channel to the slot when the reception interference power of the selected slot is equal to or less than a threshold. Take the configuration.
[0051]
The base station apparatus according to the present invention is configured such that the selection order calculating means calculates the selection order function of each slot by adding the code multiplexing number of the slot to a value obtained by multiplying the priority function of the slot by the weighting factor. take.
[0052]
The base station apparatus according to the present invention employs a configuration in which the channel allocating means allocates a channel to the slot when the received interference power of the searched slot is equal to or less than a threshold.
[0053]
The base station apparatus according to the present invention employs a configuration in which the channel allocation means increases the priority function of the slot to which the channel has been allocated.
[0054]
The base station apparatus of the present invention employs a configuration in which the channel allocating unit reduces the priority function of the slot when the received interference power of the search target slot is larger than a threshold.
[0055]
With these configurations, the priority function can be updated based on the result of the channel search, so that efficient channel allocation can be performed.
[0071]
The channel assignment method of the present invention employs a method of individually controlling the uplink / downlink priority functions for all the channels and decreasing the priority function of the same channel on the reverse link of the channel whose priority function has been increased.
[0072]
The channel assignment method of the present invention employs a method of individually controlling uplink / downlink priority functions for all channels and increasing the priority function of the same channel on the reverse link of the channel whose priority function has been lowered.
[0073]
According to these methods, the priority function of a line to which no channel is allocated can be updated. Therefore, when the upper and lower lines are switched, the channel is allocated based on the contents of the priority table reflecting the current line quality. It is possible to prevent unnecessary channel search.
[0074]
The channel allocation method of the present invention employs a method of setting the priority function of a switched channel to a predetermined value when switching between the upper and lower channels of the channel.
[0075]
According to this method, the priority function of the channel for which the uplink and downlink have been switched can be suppressed, so that it is possible to prevent sudden switching between the uplink and downlink.
[0078]
According to the channel assignment method of the present invention, there is a connection request in wireless communication of the CDMA / TDD communication system. Call Transmission rate priority function In descending order Select the search target slot, and receive interference power of the selected slot Allocates a channel to the slot when the connection rate is equal to or less than the threshold of the transmission rate of the call for which the connection request has been made. Take the way.
[0079]
According to this method, it is possible to set a threshold value for each transmission rate and select a slot in descending order of the priority function among the desired transmission rates to perform a channel search. Therefore, in the CDMA / TDD communication method, In this case, channel segregation can be performed efficiently.
[0080]
A channel assignment method according to the present invention is used in wireless communication of a CDMA / TDD communication method. Select the slot to search from among the candidate slots that have not yet been selected as search targets and that have the largest number of code multiplexes And the received interference power of the selected slot Assign a channel to the slot if is less than or equal to the threshold Take the way.
[0081]
By this method, channel search is performed in the CDMA / TDD communication method by performing channel search in the order of higher priority function in the slot having the largest number of code multiplexes.
[0082]
Further, a slot having a large number of code multiplexes is less likely to be used for communication in a peripheral base station, and is likely to have received interference power below a threshold. As a result, it is possible to shorten the time until a slot is allocated and to reduce the amount of calculation.
[0085]
BEST MODE FOR CARRYING OUT THE INVENTION
The essence of the present invention is that, in channel allocation, a channel where a call has been terminated has a high possibility of accommodating a call, so that a channel with a call terminated is preferentially searched to perform an efficient channel search. That is, the priority table is updated even at a timing other than when channel allocation is performed, such as after a certain period has elapsed or when a call is terminated.
[0086]
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
[0087]
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a communication terminal device serving as a communication partner of the base station device according to Embodiment 1.
[0088]
In FIG. 1, communication terminal apparatus 100 includes a transmitting / receiving circuit 101 for transmitting / receiving a modulated wave signal, an encoding circuit 102 for encoding a transmitted signal, and decoding desired data from a received signal demodulated by transmitting / receiving circuit 101. And a decoding circuit 103. Further, communication terminal apparatus 100 measures interference wave power from the reception signal demodulated by transmission / reception circuit 101 and outputs the result, interference power measurement circuit 104, and outputs the output from interference power measurement circuit 104 and the transmission signal. And a multiplexing circuit 105 for multiplexing and outputting to the encoding circuit 102.
[0089]
FIG. 2 is a block diagram showing a configuration of the base station apparatus according to Embodiment 1.
[0090]
2, base station apparatus 200 includes transmission / reception circuit 201 for transmitting / receiving a modulated wave signal, encoding circuit 202 for encoding a transmission signal, and decoding desired data from the reception signal demodulated by transmission / reception circuit 201. And a decoding circuit 203.
[0091]
Further, base station apparatus 200 includes a separating circuit 204 that separates information on the interference wave power transmitted from communication terminal apparatus 100 from the data decoded by decoding circuit 203, and a channel signal based on the received signal demodulated by transmitting / receiving circuit 201. A propagation path measurement circuit 205 for checking the occupation status and outputting the obtained result as channel information.
[0092]
The base station apparatus 200 further includes a channel assignment circuit 206 for assigning a channel, a priority function 207 for all slots, and a priority table 207 for recording a termination order in which the termination occurred in the slots. And a table updating circuit 208 for updating the priority table 207.
[0093]
Next, a detailed operation of the channel assignment circuit 206 and the table update circuit 208 in the channel search will be described.
[0094]
The table updating circuit 208 updates the priority information of the priority table 207 based on the channel assignment information output from the channel assignment circuit 206. Specifically, the table updating circuit 208 increases the priority value of the slot to which the channel has been allocated, and decreases the priority value of the slot to which the channel cannot be allocated. Further, when there is an end call in the slot, the table update circuit 208 records in the priority table 207 the order in which the end calls have occurred in the slot.
[0095]
When there is a request for a new channel allocation, the channel allocation circuit 206 refers to the priority table 207 to determine whether a new channel is allocated by setting the slot in which the last call has occurred as a free slot candidate. Check and if a slot is free, assign a new channel.
[0096]
If the channel allocation cannot be performed with the previously selected empty slot candidate, the channel allocation circuit 206 selects an empty slot candidate in the order of the time at which the end call occurred in time from the time of referring to the table, and allocates the channel. Find out if you can.
[0097]
Then, the channel allocation circuit 206 searches a predetermined number of slots in which a call has occurred and fails to allocate a channel, selects a free slot candidate by referring to the priority function of the priority table 207, and allocates a channel. Check.
[0098]
Next, an example of selecting an empty slot candidate will be described.
[0099]
FIG. 3 is a diagram showing an example of an internal configuration of a priority table in the base station apparatus according to Embodiment 1.
[0100]
As shown in FIG. 3, the priority table 207 stores a slot number, a slot priority function, and a termination order in which the termination occurred in the slot in association with each slot. In FIG. 3, (# 1 to # 13) indicate slot numbers. For example, the value of the priority function of slot # 3 is “0.65”, and the termination order is “3”.
[0101]
Hereinafter, an example in the case where the number of preferential search of the slot by the end call is set to “2” will be described.
[0102]
The channel assignment circuit 206 first refers to the order of termination in the priority table 207, and searches for the slot in which the call was terminated last. Specifically, the slot # 3 having the largest call termination order is searched.
[0103]
If channel assignment is not possible for slot # 3, table update circuit 208 decreases the value of the priority function for slot # 3, and channel assignment circuit 206 determines that the slot that was terminated earlier than slot # 3 Search for # 9.
[0104]
If channel assignment is not possible for slot # 9, table updating circuit 208 decreases the value of the priority function for slot # 9, and channel assignment circuit 206 determines that the number of priority searches for slots due to termination is "2". Therefore, the slots are searched for in descending order of the value of the priority function. Specifically, a slot # 1 having the highest priority function value of "0.85" among slots excluding the already searched slots # 3 and # 9 is searched.
[0105]
Thereafter, the channel assignment circuit 206 searches for slots in descending order of the value of the priority function.
[0106]
Next, a channel assignment method in base station apparatus 200 having the above configuration will be described with reference to the flowchart of FIG.
[0107]
In ST301, the channel assignment circuit 206 refers to the priority table 207 and selects a slot having a higher call termination order in which slots are terminated as a free slot candidate.
[0108]
In ST301, when there is an empty slot candidate in which a call is terminated, in ST302, channel assignment circuit 206 determines whether or not the received interference power value of the empty slot candidate is smaller than a threshold value.
[0109]
If the received interference power value is smaller than the threshold value in ST302, in ST303, table updating circuit 208 increases the value of the priority function of the empty slot candidate in priority table 207. In ST304, channel assignment circuit 206 assigns a channel to the candidate slot, and ends the process.
[0110]
If the received interference power value is equal to or larger than the threshold value in ST302, in ST305, table updating circuit 208 decreases the value of the priority function of the empty slot candidate in priority table 207. In ST306, channel allocation circuit 206 removes the vacant slot candidate whose received interference power value is equal to or larger than the threshold from the candidates, and returns to ST301.
[0111]
In ST301, when there is no empty slot candidate in which the call has ended, in ST307, channel assignment circuit 206 refers to priority table 207 and selects a slot having a higher priority function value as an empty slot candidate.
[0112]
If there is no empty slot candidate in ST307, in ST308, channel assignment circuit 206 performs a call loss process and ends the process.
[0113]
If there is an empty slot candidate in ST307, in ST309, channel assignment circuit 206 determines whether or not the received interference power value of the empty slot candidate is smaller than a threshold. .
[0114]
If the received interference power value is equal to or greater than the threshold value in ST309, in ST310, table updating circuit 208 decreases the value of the priority function of the empty slot candidate in priority table 207. In ST311, channel allocation circuit 206 removes the empty slot candidates whose received interference power value is equal to or larger than the threshold from the candidates, and returns to ST307.
[0115]
As described above, according to the wireless communication apparatus of the present embodiment, by preferentially searching for the channel on which the call has been terminated, the channel on which the call has been terminated has a high possibility of accommodating the call. Can be preferentially searched for a channel capable of accommodating, so that efficient channel allocation can be performed.
[0116]
Further, according to the wireless communication apparatus of the present embodiment, it is possible to search for a channel on which a call has been terminated, and to find a channel that can accommodate a call even if no accommodating channel is found. .
[0117]
In addition, the expiration date of a predetermined time may be provided in the information of the termination order in which the termination occurred in the slot. For example, the table update circuit 208 deletes, from the priority table 207, information on the order in which the call ends after a predetermined time has elapsed from the time when the end call occurred.
[0118]
In this way, the information of the order of the channel in which the call was generated is deleted after a predetermined time elapses, and the channel that has a low possibility of accommodating the call is preferentially excluded from the search target. Channels that can be accommodated can be searched preferentially, so that efficient channel allocation can be performed.
[0119]
(Embodiment 2)
FIG. 5 is a diagram showing an example of an internal configuration of a priority table in the base station apparatus according to Embodiment 2.
[0120]
As shown in FIG. 5, the priority table 207 stores a slot number, a slot priority function, and a termination order in which a termination occurs in a slot in association with each other, as shown in FIG. In FIG. 5, (# 1 to # 13) indicate slot numbers. For example, the value of the priority function of slot # 3 is “0.65”, and the termination order is “3”.
[0121]
When channel assignment is performed by the wireless communication apparatus according to the first embodiment, the wireless communication apparatus refers to the priority table shown in FIG. Since the channel search is performed by selecting an empty slot candidate retrospectively, the channel search is performed for the slot # 11 where the end call was last and then for the slot # 13.
[0122]
However, slot # 11 and slot # 13 have low values of the priority function, and there is a possibility that these slots are used in other cells, and there is a high possibility that channel interference cannot be allocated due to large interference.
[0123]
Therefore, in the present embodiment, in order to solve the above problem, when a large number of temporary calls occur temporarily, a predetermined number of slots are compared by comparing the size of the priority function value with the slot where the final call occurred. , And preferentially search for slots that are unlikely to accommodate calls.
[0124]
Hereinafter, a case will be described as an example where priority search is performed on slots up to the second slot in descending order of the value of the priority function and the slot in which the end call has occurred.
[0125]
When there is a request for a new channel assignment, the channel assignment circuit 206 refers to the priority table 207 and determines the slots up to the second in descending order of the value of the priority function and the slot in which the termination call has occurred as an empty slot candidate. And checks whether a new channel is allocated, and if a slot is available, allocates a new channel.
[0126]
In the example of FIG. 5, slot # 5 satisfies the condition and is selected as an empty slot candidate.
[0127]
If the channel allocation circuit 206 searches for an empty slot candidate under the above conditions and fails to allocate a channel, the channel allocation circuit 206 refers to the priority function of the priority table 207 to select an empty slot candidate and checks whether a channel is allocated. .
[0128]
As described above, according to the wireless communication device of the present embodiment, when a large number of temporary calls are temporarily generated, a comparison is made between the channel on which the call was terminated and the value of the priority function. By preferentially searching for a channel having a predetermined rank or higher and excluding a channel having a low possibility of accommodating a call from priority search targets, it is possible to limit the number of priority channel searches due to a call termination.
[0129]
In Embodiments 1 and 2, the respective channels can be assigned to the uplink and the downlink. In addition, when upper and lower lines are assigned in pairs, the base station device only needs to have one of the line priority tables. The first and second embodiments can also be applied to multiplex communication such as frequency division multiplex communication. In this case, a plurality of existing channels are searched by frequency division or the like instead of slots used in time division multiplex communication, and are assigned to channels accommodating calls.
[0130]
(Embodiment 3)
Here, in the TDD communication method, when switching between the upper and lower lines of the slot to cope with the asymmetric traffic, the priority table used for the channel search is switched at the same time as the switching. However, the conventional channel allocation method does not consider competition and switching between the uplink and the downlink in each channel, so that there is a problem that efficient operation cannot be performed accordingly.
[0131]
In the third embodiment, in order to solve this problem, a case will be described in which uplink and downlink priority functions are individually controlled for all channels, and a channel on the reverse channel of the channel on which the channel search is performed is controlled. I do.
[0132]
FIG. 6 is a block diagram showing a configuration of the base station apparatus according to the present embodiment. In addition, in the base station apparatus 400 of FIG. 6, the same components as those of the base station apparatus 200 of FIG. Further, the communication terminal apparatus according to the present embodiment has the same configuration as communication terminal apparatus 100 shown in FIG.
[0133]
The base station apparatus 400 in FIG. 6 differs from the base station apparatus 200 in FIG. 2 in that the propagation path measurement circuit 205, the channel allocation circuit 206, and the table update circuit 208 are deleted, the interference power measurement circuit 401, the uplink priority A configuration in which a table 402, a downlink priority table 403, and a channel assignment circuit 404 are added is adopted.
[0134]
The interference power measurement circuit 401 measures the interference wave power from the received signal demodulated by the transmission / reception device 201 and outputs the result. An uplink priority table 402 and a downlink priority table 403 are provided for each channel, and the uplink priority table 402 records uplink priority functions for all channels. The downlink priority table 403 records downlink priority functions for all channels.
[0135]
The channel assignment circuit 404 determines the channel in the uplink or downlink based on the interference power measured in the communication terminal 100, the interference power measured in the base station 400, and the uplink / downlink identification signal. Assignment is performed, and after the channel is assigned, the uplink priority table 402 and the downlink priority table 403 are updated. For channel assignment, when there are many downlink channel assignment requests, the number of downlink channel assignments increases, and the priority table also has a large number of downlink priority functions. Conversely, when there are many uplink channel assignment requests, the number of uplink channel assignments increases, and the priority table also has more uplink priority functions. The uplink / downlink identification signal is generated from inside the base station apparatus 400. For example, when channel assignment is performed by a radio network controller (RNC), the apparatus becomes an RNC apparatus.
[0136]
At the time of channel assignment, a signal indicating a slot for measuring interference wave power is transmitted from base station apparatus 400 to communication terminal apparatus 100. Upon receiving the instruction, communication terminal apparatus 100 measures the interference wave power for the slot to be measured, and transmits the result to base station apparatus 400. Base station apparatus 400 outputs the interference wave power value reported from communication terminal apparatus 100 to channel assignment circuit 404, measures the interference wave power in the slot in its own station, and reports the result to channel assignment circuit 404. Output to The channel assignment circuit 404 receives a slot number to be assigned and an uplink / downlink identification signal in addition to the interference wave power value.
[0137]
Next, a channel assignment operation in communication terminal apparatus 100 and base station apparatus 400 having the above configurations will be described. The operation of communication terminal apparatus 100 and base station apparatus 400 will not be described separately but will be described collectively.
[0138]
(Channel assignment)
FIG. 7 is a flowchart showing channel assignment processing according to the present embodiment.
[0139]
First, in ST501, uplink and downlink are determined. In the case of the uplink, the mobile terminal proceeds to ST502 and performs channel assignment for the uplink. In the case of a downlink, the process proceeds to ST503 and channel assignment for the downlink is performed.
[0140]
As described above, base station apparatus 400 has uplink priority table 402 and downlink priority table 403 for each channel, so, for example, when there are many downlink channel assignment requests, As the number of times increases, the priority function of the downlink table also increases in the priority table.
[0141]
(Uplink channel assignment processing)
FIG. 8 is a flowchart showing uplink channel assignment processing according to the present embodiment.
[0142]
When there is an uplink channel assignment request, base station apparatus 400 measures the interference power (interference U) of the channel having a high priority function and not “busy” in ST601.
[0143]
Next, in ST602, base station apparatus 400 compares interference power U with threshold value U1. In this comparison, if the interference power U is smaller than the threshold value U1, it is determined that uplink reception quality can be ensured because the uplink interference power is small. Therefore, when interference power U is smaller than threshold value U1 (in the case of YES), the corresponding channel is allocated to the uplink in ST603. Then, in ST604, the uplink priority function of the channel is increased. Next, in ST605, the downlink priority function of the channel is lowered.
[0144]
On the other hand, if the interference power U is equal to or larger than the threshold value U1 in ST602 (NO), the uplink of the channel is set to "busy" in ST606. Then, in ST607, the uplink priority function of the channel is lowered. Next, in ST608, the downlink priority function of the channel is increased.
[0145]
Next, in ST609, it is determined whether or not the measurement has been completed for all the channels. If the interference power U is equal to or greater than the threshold value U1 for all channels, it is determined in ST610 that channel allocation is impossible, and the process exits.
[0146]
(Downlink channel assignment processing)
FIG. 9 is a flowchart showing downlink channel assignment processing according to the present embodiment.
[0147]
When there is a downlink channel allocation request, base station apparatus 400 causes communication terminal apparatus 100 to measure interference wave power (interference D) of a channel having a high priority function and not being "busy" in ST701. Report the results.
[0148]
Next, in ST702, base station apparatus 400 compares interference power D with threshold value D1. In this comparison, when the interference power D is smaller than the threshold value D1, it is determined that downlink reception quality can be ensured because downlink interference is small. Therefore, when interference power D is smaller than threshold value D1 (in the case of YES), in ST703, the channel is allocated to the downlink. Then, in ST704, the downlink priority function of the channel is increased. Next, in ST705, the uplink priority function of the channel is lowered.
[0149]
On the other hand, when the interference power D is larger than the threshold value D1 in ST702 (NO), the downlink of the channel is set to “busy” in ST706. Then, in ST707, the downlink priority function of the channel is lowered. Next, in ST708, the uplink priority function of the channel is increased.
[0150]
Next, in ST709, it is determined whether or not the measurement has been completed for all channels. If there are remaining channels, the process is repeated from ST701. If interference power D is greater than threshold value D1 for all channels, it is determined in ST710 that channel allocation is impossible, and the process exits.
[0151]
As described above, according to the present embodiment, a priority table dedicated to “uplink” and a priority table dedicated to “downlink” are prepared and individually controlled, so that uplink / downlink allocation is mixed. Even in such a case, efficient operation can be performed.
[0152]
Then, by lowering the priority function of the reverse channel of the channel whose priority function has been raised, or raising the priority function of the reverse channel of the channel whose priority function has been lowered, the The priority function can be updated at any time. As a result, it is possible to perform channel assignment based on the contents of the priority table reflecting the current line quality when the upper and lower lines are switched, and to prevent unnecessary channel search.
[0153]
Here, when the priority function is high at the time of line switching, it leads to sudden switching of the upper and lower lines. This is not preferable due to the influence of disturbance or the like.
[0154]
On the other hand, the channel assignment circuit 404 may reset the priority function of the channel to a predetermined value such as a median value when switching the upper and lower lines of the channel. As a result, it is possible to suppress the priority function of the channel in which the uplink and downlink are switched, so that it is possible to prevent sudden switching between the uplink and downlink, and to reduce the amount of calculation for calculating the priority function. Reduction can be achieved.
[0155]
(Process of updating priority function of channel assignment at handover)
Next, with reference to a flowchart shown in FIG. 10, a description will be given of a process of updating the priority function of channel assignment at the time of handover.
[0156]
The following two points or a combination thereof can be considered as a trigger for the handover.
[0157]
(1) When desired wave power decreases due to movement of communication terminal device
(2) When the interference wave power increases due to the start of transmission by another base station device or mobile device
In the case of the above (2), when handover occurs even though the desired wave power is small, it can be said that the channel at that time is susceptible to interference and that the interference makes it difficult to maintain communication.
[0158]
Therefore, in ST801 of FIG. 10, the magnitude of the desired wave power and the increase amount of the interference wave power are determined. Then, when the fluctuation of the desired wave power is small and the interference wave power is increased, the uplink (or downlink) priority function of the channel is lowered in ST802.
[0159]
As described above, when the interference signal increases due to the start of communication of another base station or mobile station, and a handover is required due to this, the priority function of the channel susceptible to interference is lowered, so that the opportunity for the handover is reduced. Can be reduced.
[0160]
The flow chart is programmed and stored as data in a memory or the like, and a control unit (not shown) performs channel assignment control according to the stored program. This program is of course divided for the communication terminal device 100 and the base station device 400.
[0161]
(Embodiment 4)
FIG. 11 is a block diagram showing a configuration of a communication terminal apparatus serving as a communication partner of the base station apparatus according to Embodiment 4 of the present invention. Communication terminal apparatus 900 includes a multiplexing circuit 901, a modulation circuit 902, a spreading circuit 903, a transmission / reception circuit 904, a despreading circuit 905, a demodulation circuit 906, a separation circuit 907, and an interference power measurement circuit 908. It is mainly composed.
[0162]
The multiplexing circuit 901 multiplexes the interference power information output from the interference power measuring circuit 908 and the transmission signal and outputs the multiplexed signal to the modulation circuit 902. Modulation circuit 902 performs primary modulation such as QPSK on the output signal of multiplexing circuit 901 and outputs the result to spreading circuit 903. Spreading circuit 903 multiplies the output signal of modulation circuit 902 by a predetermined spreading code, and outputs the result to transmission / reception circuit 904.
[0163]
The transmission / reception circuit 904 transmits / receives a modulated wave signal in the assigned slot. Specifically, the output signal of the spreading circuit 903 is converted to a radio frequency, amplified, and transmitted by radio from an antenna. Further, the signal received by the antenna is amplified and frequency-converted to baseband, and output to the despreading circuit 905.
[0164]
Despreading circuit 905 multiplies the output signal of transmission / reception circuit 904 by the same spreading code as that of the communication partner, and outputs the result to demodulation circuit 906 and interference power measurement circuit 908. Demodulation circuit 906 demodulates the output signal of despreading circuit 905 and outputs it to separation circuit 907. Separation circuit 907 separates channel assignment information from the output signal of demodulation circuit 906 and outputs the result to transmission / reception circuit 904. Interference power measurement circuit 908 measures downlink interference power from the output signal of despreading circuit 905 and outputs the measurement result to multiplexing circuit 901 as interference power information.
[0165]
FIG. 12 is a block diagram showing a configuration of the base station apparatus according to the present embodiment. The base station apparatus 1000 includes a multiplexing circuit 1001, a modulation circuit 1002, a spreading circuit 1003, a transmission / reception circuit 1004, a despreading circuit 1005, a demodulation circuit 1006, a separation circuit 1007, an interference power measurement circuit 1008, It mainly comprises a line priority table 1009, a downlink priority table 1010, a timing control circuit 1011, a slot selection circuit 1012, and a channel allocation circuit 1013.
[0166]
The multiplexing circuit 1001 multiplexes the channel assignment information output from the channel assignment circuit 1013 with the transmission signal and outputs the multiplexed signal to the modulation circuit 1002. Modulation circuit 1002 performs primary modulation such as QPSK on the output signal of multiplexing circuit 1001 and outputs the result to spreading circuit 1003. Spreading circuit 1003 multiplies the output signal of modulation circuit 1002 by a predetermined spreading code, and outputs the result to transmission / reception circuit 1004.
[0167]
The transmission / reception circuit 1004 transmits / receives a modulated wave signal in the assigned slot. Specifically, the output signal of the spreading circuit 1003 is converted into a radio frequency, amplified, and transmitted by radio from an antenna. Further, the signal received by the antenna is amplified and frequency-converted to baseband, and output to the despreading circuit 1005.
[0168]
Despreading circuit 1005 multiplies the output signal of transmitting / receiving circuit 1004 by the same spreading code as that of the communication partner, and outputs the result to demodulation circuit 1006 and interference power measurement circuit 1008. Demodulation circuit 1006 demodulates the output signal of despreading circuit 1005 and outputs it to separation circuit 1007. Separation circuit 1007 separates interference power information from the output signal of demodulation circuit 1006 and outputs the result to channel assignment circuit 1013. Interference power measurement circuit 1008 measures uplink reception interference power from the output signal of despreading circuit 1005 and outputs the measurement result to channel assignment circuit 1013.
[0169]
The uplink priority table 1009 records an uplink priority function and the number of code multiplexes for each slot. The downlink priority table 1010 records a downlink priority function and the number of code multiplexes for each slot.
[0170]
The timing control circuit 1011 instructs the slot selection circuit 1012 and the channel allocation circuit 1013 to start the priority table update processing at a predetermined timing.
[0171]
The slot selection circuit 1012 performs a slot search (hereinafter, referred to as a “channel”) based on the priority function recorded in the uplink priority table 1009 or the downlink priority table 1010 at the timing designated by the timing control circuit 1011. Search slot).
[0172]
The channel allocation circuit 1013 determines the magnitude relationship between the channel quality estimation value such as the reception interference power of the search target slot and the threshold at the time of the call connection request, performs channel allocation processing based on the determination result, and performs an uplink priority table. 1009 or the downlink priority table 1010 is updated. Even at a timing other than the time of the call connection request, the channel assignment circuit 1013 updates the uplink priority table 1009 or the downlink priority table 1010 at the timing specified by the timing control circuit 1011 as needed.
[0173]
Next, the procedure of the priority table update process according to the present embodiment will be described using the flowchart of FIG. FIG. 13 shows a case where the priority table updating process is performed after a predetermined frame period has elapsed.
[0174]
In ST1101, when timing control circuit 1011 detects that a predetermined frame period has elapsed, in ST1102, slot selection circuit 1012 selects a search target slot, and in ST1103, channel assignment circuit 1013 obtains reception interference power.
[0175]
Note that the uplink received interference power is measured by interference power measurement circuit 1008 of base station apparatus 1000 and output to channel assignment circuit 1013. On the other hand, downlink interference power is measured by communication terminal apparatus 100, and the measurement result is transmitted to base station apparatus 1000 as interference power information. Then, interference power information is separated by separation circuit 1007 of base station apparatus 1000 and output to channel assignment circuit 1013.
[0176]
Then, in ST1104, channel allocation circuit 1013 determines the magnitude relationship between the reception interference power of the search target slot and the threshold value, and if the reception interference power is equal to or less than the threshold value, in ST1105, channel allocation circuit 1013 determines the priority of the search target slot. Raise the degree function. On the other hand, if the received interference power is larger than the threshold, in ST1106, channel assignment circuit 1013 lowers the priority function of the search target slot.
[0177]
Then, in ST1107, the steps from ST1102 to ST1106 are repeated for all slots.
[0178]
As described above, by performing the priority table update processing at every fixed frame period, the contents of the priority table can be updated at any time, so that the base station apparatus can update the contents of the priority table reflecting the current line quality. Can be assigned based on
[0179]
Here, along with a change in the connection state of the call such as a termination call or an intra-cell handover request, the propagation path quality and the channel assignment availability determination change. Therefore, in order to reflect the current line quality in the priority table, it is necessary to update the priority table at these timings.
[0180]
In this case, when a call termination or an intracell handover request occurs, the timing control circuit 1011 instructs the slot selection circuit 1012 and the channel allocation circuit 1013 to start the priority table update processing. The slot selection circuit 1012 and the channel allocation circuit 1013 perform the same processing as ST1102 to ST1107 in FIG.
[0181]
As a result, the contents of the priority table can be made to correspond to the line quality changed according to the call connection status.
[0182]
Although the present embodiment has been described using the received interference power as the estimated channel quality value, the present invention is not limited to this, and similar effects can be obtained by using other estimated channel quality values. .
[0183]
(Embodiment 5)
Here, in the case of a CDMA (Code Division Multiple Access) / TDD (Time Division Duplex) communication system, a channel is defined by a time slot (hereinafter simply referred to as a "slot") and a code, and a plurality of calls can be code-multiplexed. it can.
[0184]
Code pooling that increases the number of multiplexed codes in each slot and reduces the number of occupied slots is more effective in terms of frequency utilization efficiency than slot pooling that increases the number of occupied slots and reduces the number of code multiplexes in each slot. It is known that
[0185]
In the fifth embodiment, a description will be given of a priority table update process capable of maintaining a code pooling state in the case of the CDMA / TDD communication method.
[0186]
FIG. 14 is a flowchart showing the procedure of the priority table update process according to the present embodiment. FIG. 14 shows a case in which the priority table updating process is performed every fixed frame period.
[0187]
When the timing control circuit 1011 detects that a predetermined frame period has elapsed in ST1201, the slot selection circuit 1012 selects a search target slot in ST1202.
[0188]
Next, in ST1203 and ST1204, channel assignment circuit 1013 measures the number of multiplexed codes in the search target slot, and determines the magnitude relationship between the number of multiplexed codes and the threshold.
[0189]
If the number of multiplexed codes is equal to or smaller than the threshold, in ST1205, channel assignment circuit 1013 lowers the priority function of the search target slot. On the other hand, when the code multiplexing number is larger than the threshold, in ST1206, channel assignment circuit 1013 increases the priority function of the search target slot.
[0190]
Then, in ST1207, the steps from ST1202 to ST1206 are repeated for all slots.
[0191]
As described above, by increasing the priority function of a slot having a large number of code multiplexes, a channel search is performed from a slot having a large number of code multiplexes at the time of channel assignment, so that a code pooling state can be maintained.
[0192]
In this embodiment, a case has been described in which the priority table updating process is performed every fixed frame period. However, as described in the fourth embodiment, the connection status of a call such as a termination call or an intracell handover request is determined. The priority table updating process may be started at the timing when the change has occurred.
[0193]
(Embodiment 6)
Here, in the case of the CDMA / TDD communication system, the number of codes that can be multiplexed in each slot changes according to the transmission rate. Therefore, in the case of the multi-rate transmission system, transmission is required to realize efficient channel segregation. Rate needs to be considered.
[0194]
In the sixth embodiment, paying attention to this point, in the CDMA / TDD communication system, a threshold and a priority function are set for each transmission rate, and slots are selected in descending order of the priority function with respect to the requested transmission rate. A case of performing a channel search will be described.
[0195]
FIG. 15 is a block diagram showing a configuration of the base station apparatus according to the present embodiment. In addition, in the base station apparatus 1300 of FIG. 15, the same components as those of the base station apparatus 1000 of FIG. Further, the communication terminal apparatus according to the present embodiment has the same configuration as communication terminal apparatus 900 shown in FIG.
[0196]
The base station apparatus 1300 in FIG. 15 differs from the base station apparatus 1000 in FIG. 12 in that an uplink priority table 1009, a downlink priority table 1010, a timing control circuit 1011, a slot selection circuit 1012, and a channel assignment circuit 1013 are provided. A configuration is adopted in which the uplink priority table 1301, the downlink priority table 1302, the slot selection circuit 1303, and the channel assignment circuit 1304 are added.
[0197]
Separation circuit 1007 separates interference power information from the output signal of demodulation circuit 1006 and outputs the result to channel assignment circuit 1304. Separation circuit 1007 separates a signal indicating a desired transmission rate when there is a call connection request, and outputs the signal to slot selection circuit 1303 and channel assignment circuit 1304.
[0198]
Interference power measurement circuit 1008 measures uplink reception interference power from the output signal of despreading circuit 1005, and outputs the measurement result to channel assignment circuit 1304.
[0199]
The uplink priority table 1301 records a threshold value for each transmission rate, and records an uplink priority function for each slot and each transmission rate. The downlink priority table 1302 records a threshold value for each transmission rate, and records a downlink priority function for each slot and each transmission rate.
[0200]
When a signal indicating the transmission rate is input from the demultiplexing circuit 1007, the slot selection circuit 1303 searches for the signal based on the priority function of the transmission rate recorded in the uplink priority table 1301 or the downlink priority table 1302. Select a slot.
[0201]
The channel allocation circuit 1304 receives the reception interference power of the search target slot from the interference power measurement circuit 1008 or the separation circuit 1007 and performs a channel search. Specifically, a magnitude relationship between the reception interference power of the search target slot and the threshold of the transmission rate recorded in the uplink priority table 1301 or the downlink priority table 1302 is determined, and the reception interference power of the search target slot is determined. Is less than or equal to the threshold, the channel is assigned to the search target slot.
[0202]
When performing uplink channel assignment, interference power measurement circuit 1008 of base station apparatus 1300 measures the reception interference power of the search target slot, and outputs the measurement result to channel assignment circuit 1304. On the other hand, when performing downlink channel assignment, communication terminal apparatus 900 measures the reception interference power of the search target slot, and transmits the measurement result to base station apparatus 1300 as interference power information. Then, separation circuit 1007 of base station apparatus 1300 outputs the received interference power information to channel assignment circuit 1304.
[0203]
Then, channel assignment circuit 1304 updates uplink priority table 1301 and downlink priority table 1302 after channel assignment and the like. By updating the priority function based on the result of the channel search, efficient channel assignment can be performed.
[0204]
Further, channel assignment circuit 1304 outputs channel assignment information indicating the assigned slot to multiplexing circuit 1001 or transmitting / receiving circuit 1004.
[0205]
FIG. 16 is a diagram showing the internal configuration of the uplink priority table 1301. As shown in FIG. 16, the uplink priority table 1301 records a threshold value for each transmission rate, and records an uplink priority function for each slot and each transmission rate. In FIG. 16, (# 0-14) indicate slot numbers, respectively. For example, in the case of FIG. 16, the threshold of the transmission rate of 8 kbps is “2.5 dB”, and the priority function of the uplink in the transmission rate of 8 kbps and slot # 0 is “0.25”. Note that, similarly to the uplink priority table 1301, the downlink priority table 1302 records a threshold value for each transmission rate, and records a downlink priority function for each slot and each transmission rate.
[0206]
Next, an uplink channel assignment method in base station apparatus 1300 having the above configuration will be described with reference to the flowchart of FIG.
[0207]
First, when there is a call connection request, a signal indicating the transmission rate of the timing control circuit 1303 and the channel assignment circuit 1304 is output from the separation circuit 1007, and the timing control circuit 1303 selects a priority function of the transmission rate and assigns a channel. Circuit 1304 selects a threshold value for the transmission rate (ST1401). Next, slot selection circuit 1303 selects a search target slot at the transmission rate (ST1402), channel allocation circuit 1304 obtains reception interference power (ST1403), and the magnitude relationship between reception interference power and the threshold of the transmission rate is determined. Is determined (ST1404).
[0208]
If the received interference power is equal to or less than the threshold in the determination of ST 1404, channel assignment circuit 1304 increases the priority function of the search target slot of the transmission rate in uplink priority table 1301 (ST 1405), Channels are allocated (ST1406).
[0209]
On the other hand, if the received interference power is larger than the threshold in the determination of ST 1404, channel allocation circuit 1304 decreases the priority function of the search target slot in uplink priority table 1301 (ST 1407), and slot selection circuit 1303 The slot is excluded from the candidates (ST1408).
[0210]
If there is an unsearched slot, the process returns to ST1402 (ST1409). On the other hand, if there is no unsearched group in ST1409, the base station apparatus determines that a call has been lost (ST1410).
[0211]
In addition, channel assignment can be performed in the same manner for the downlink.
[0212]
In the case of FIG. 16 described above, since the slot priority function at the transmission rate of 12.2 kbps is $ 5, which is the highest at "0.81", the slot selection circuit 1303 first selects $ 5 as the search target slot.
[0213]
Then, as a result of the channel search in the channel assignment circuit 1304, if the received interference power of # 5 is larger than the predetermined threshold (2.9 dB), the slot selection circuit 1303 selects # 12 having the next highest priority function as the search target slot. Select as
[0214]
As described above, by setting a threshold value for each transmission rate, selecting a slot in descending order of the priority function among the desired transmission rates, and performing a channel search, the CDMA / TDD communication method can be used in a multi-rate transmission method. Channel separation can be performed efficiently.
[0215]
(Embodiment 7)
In the seventh embodiment, a case will be described where the order of slots to be searched is determined in consideration of a priority function and the number of multiplexed codes in order to realize channel segregation that naturally results in code pooling in a CDMA / TDD communication system.
[0216]
FIG. 18 is a block diagram showing a configuration of the base station apparatus according to the present embodiment. Note that, in the base station apparatus 1500 of FIG. 18, the same components as those of the base station apparatus 1000 of FIG. Further, the communication terminal apparatus according to the present embodiment has the same configuration as communication terminal apparatus 900 shown in FIG.
[0217]
The base station apparatus 1500 in FIG. 18 is different from the base station apparatus 1000 in FIG. 12 in that an uplink priority table 1009, a downlink priority table 1010, a timing control circuit 1011, a slot selection circuit 1012, and a channel assignment circuit 1013 are provided. A configuration is adopted in which an uplink priority table 1501, a downlink priority table 1502, a slot selection circuit 1503, and a channel assignment circuit 1504 are added and deleted.
[0218]
Separation circuit 1007 separates interference power information from the output signal of demodulation circuit 1006 and outputs the result to channel assignment circuit 1504. Interference power measurement circuit 1008 measures uplink reception interference power from the output signal of despreading circuit 205 and outputs the measurement result to channel assignment circuit 1504.
[0219]
The uplink priority table 1501 records an uplink priority function and the number of code multiplexes for each slot. The downlink priority table 1502 records a downlink priority function and the number of code multiplexes for each slot.
[0220]
The slot selection circuit 1503 selects a search target slot based on the priority function and the number of code multiplexes recorded in the uplink priority table 1501 or the downlink priority table 1502.
[0221]
The channel allocation circuit 1504 inputs the received interference power of the search target slot from the interference power measurement circuit 1008 or the separation circuit 1007, and performs a channel search. Specifically, a magnitude relationship between the reception interference power of the search target slot and the threshold is determined. If the reception interference power of the search target slot is equal to or less than the threshold, a channel is assigned to the search target slot, If the power is larger than the threshold, the slot selection circuit 1503 is requested to search for the next slot to be searched.
[0222]
When uplink channel allocation is performed, interference power measurement circuit 1008 of base station apparatus 1500 measures the reception interference power of the search target slot and outputs the measurement result to channel allocation circuit 1504. On the other hand, when performing downlink channel allocation, communication terminal apparatus 900 measures the reception interference power of the search target slot, and transmits the measurement result to base station apparatus 1500 as interference power information. Then, demultiplexing circuit 1007 of base station apparatus 1500 outputs the received interference power information to channel assignment circuit 1504.
[0223]
Then, channel assignment circuit 1504 updates uplink priority table 1501 and downlink priority table 1502 after channel assignment and the like. By updating the priority function based on the result of the channel search, efficient channel assignment can be performed.
[0224]
Further, channel assignment circuit 1504 outputs channel assignment information indicating the assigned slot to multiplexing circuit 1001 or transmitting / receiving circuit 1004.
[0225]
FIG. 19 is a diagram showing an internal configuration of the uplink priority table 1501. In FIG. 19, (# 0-14) indicate slot numbers, respectively. For example, in the case of FIG. 19, the priority function of the uplink in slot # 0 is “0.25”, and the number of multiplexed codes is “1”. The downlink priority table 1502 also records the downlink priority function and the number of code multiplexes for each slot, similarly to the uplink priority table 1501.
[0226]
Next, an uplink channel assignment method in base station apparatus 1500 having the above configuration will be described using the flowchart of FIG.
[0227]
First, slot selection circuit 1503 refers to the code multiplexing number of each slot recorded in uplink priority table 1501, and groups slots according to the code multiplexing number (ST1601). Then, slot selecting circuit 1503 sets a group having the largest code multiplexing number among unsearched groups as a priority group (ST1602).
[0228]
Next, the slot selection circuit 1503 refers to the priority function of each slot recorded in the uplink priority table 1501, and determines the most suitable slot among the slots belonging to the priority group (hereinafter referred to as “selection candidate slot”). A slot having a higher priority function is selected as a search target slot (ST1603).
[0229]
Next, interference power measurement circuit 1008 measures the received interference power of the search target slot (ST1604), and channel allocation circuit 1504 determines the magnitude relationship between the received interference power and the threshold (ST1605).
[0230]
If it is determined in ST1605 that the received interference power is equal to or smaller than the threshold, channel allocation circuit 1504 increases the priority function of the search target slot in uplink priority table 1501 (ST1606), and allocates a channel to the search target slot (ST1606). ST1607).
[0231]
On the other hand, when the received interference power is larger than the threshold in ST1605, channel allocation circuit 1504 decreases the priority function of the search target slot in uplink priority table 1501 (ST1608), and slot selection circuit 1503 searches for the target slot. The slot is removed from the candidates (ST1609).
[0232]
If there is still a selection candidate slot in the priority group, the process returns to ST1603 (ST1610). On the other hand, if there is no selection candidate slot in the priority group in ST1610, slot selection circuit 1503 removes the group from the priority group (ST1611).
[0233]
If there is an unsearched group, the process returns to ST1602 (ST1612). On the other hand, if there is no unsearched group in ST1612, the base station apparatus sets a call loss (ST1613).
[0234]
In addition, channel assignment can be performed in the same manner for the downlink.
[0235]
In the case of FIG. 19, the maximum code multiplexing number is “6”, and the selection candidate slots belonging to the priority group are # 1, # 5, and # 12. Since the priority functions of the selection candidate slots # 1, # 5, and # 12 are "0.56", "0.73", and "0.61", respectively, the slot selection circuit 1503 first searches for $ 5. Select as target slot.
[0236]
Then, as a result of the channel search in channel assignment circuit 1504, if the received interference power of # 5 is larger than a predetermined threshold, slot selection circuit 1503 next selects # 12 as a search target slot.
[0237]
As described above, by performing the channel search in the order of the priority function in the slot having the largest number of code multiplexes, it is possible to naturally perform channel segregation that is code pooling in the CDMA / TDD communication system.
[0238]
Further, a slot having a large number of code multiplexes has a low possibility of being used for communication in a peripheral base station and has a high possibility that the reception interference power is equal to or lower than a threshold value. As a result, it is possible to shorten the time until a slot is allocated and to reduce the amount of calculation.
[0239]
(Embodiment 8)
FIG. 21 is a block diagram showing a configuration of a base station apparatus according to Embodiment 8 of the present invention. In addition, in the base station apparatus 1700 shown in FIG. 21, the same components as those of the base station apparatus 1500 shown in FIG. Also, the configuration of the communication terminal device that is the communication partner of the base station device according to the present embodiment is the same as that of FIG.
[0240]
The base station apparatus 1700 shown in FIG. 21 has a configuration in which a selection order calculation circuit 1701 is added, and differs from the base station apparatus 1700 shown in FIG. 18 in the operation content of the slot selection circuit 1503.
[0241]
The selection order calculation circuit 1701 calculates a selection order function pn from the following equation (1) using the priority function vn and the code multiplex number Mn as parameters (parameters). In Equation (1), n is a slot number, and α is a weighting coefficient.
[0242]
pn = vn + αMn (1)
The slot selection circuit 1503 selects a slot having the highest selection order function pn among slots that have not been selected as a search target slot.
[0243]
As described above, the channel search is performed in descending order of the priority function of each slot and the selection order function using the number of code multiplexes of each slot as a parameter as a parameter, whereby channel segregation that naturally results in code pooling in the CDMA / TDD communication system It can be performed.
[0244]
(Embodiment 9)
Here, the code multiplexing status in each slot changes due to a call termination or the like. On the other hand, if the slot assigned once in each channel does not change until the end of the call, the state of code pooling will be lost.
[0245]
In the ninth embodiment, in consideration of this point, a case will be described in which a slot allocated to each channel is changed in response to a change in a situation in a CDMA / TDD communication system so as to maintain a code pooling state. Specifically, intra-cell handover (hereinafter, referred to as "IHO"), which has been used to improve the communication quality of a call that has been degraded due to interference, is used to implement code pooling.
[0246]
FIG. 22 is a block diagram showing a configuration of the base station apparatus according to the present embodiment. In the base station apparatus 1800 of FIG. 22, the same components as those of the base station apparatus 1000 of FIG. Further, the communication terminal apparatus according to the present embodiment has the same configuration as communication terminal apparatus 900 shown in FIG.
[0247]
The base station apparatus 1800 in FIG. 22 is different from the base station apparatus 1000 in FIG. 12 in that an uplink priority table 1009, a downlink priority table 1010, a timing control circuit 1011, a slot selection circuit 1012, and a channel assignment circuit 1013 are provided. The configuration is such that the uplink priority table 1801, the downlink priority table 1802, the timing control circuit 1803, the slot selection circuit 1804, and the IHO execution circuit 1805 are added.
[0248]
Separation circuit 1007 separates interference power information from the output signal of demodulation circuit 1006 and outputs the result to IHO execution circuit 1805. Interference power measuring circuit 1008 measures the uplink received interference power from the output signal of despreading circuit 1005, and outputs the measurement result to IHO execution circuit 1805.
[0249]
The uplink priority table 1801 records an uplink priority function and the number of code multiplexes for each slot. The downlink priority table 1802 records a downlink priority function and the number of code multiplexes for each slot.
[0250]
The timing control circuit 1803 instructs the slot selection circuit 1804 and the IHO execution circuit 1805 to start IHO. The timing at which the timing control circuit 1803 instructs the start of the IHO includes a timing at which a call connection request is made, a timing at which a call is terminated, after a certain frame period has elapsed, and the like, and each has a specific effect.
[0251]
By performing IHO at the timing of a call connection request, the number of code multiplexes and the number of occupied slots required by the call can be considered, so that IHO can be performed most directly to accommodate the call. it can. For example, when there is a call connection request of one slot for one code and three slots for eight codes, IHO is performed until resources satisfying the request are secured. Therefore, the effect of reducing the call loss rate can be obtained.
[0252]
In addition, by performing IHO at the timing when there is a call, there is a vacant slot in which the call has been made, so that the effect that the probability of success of IHO is high can be obtained.
[0253]
However, if the IHO is performed at the timing of a call connection request or at the timing of termination, the contents of the priority table may not be updated for a long time. In this case, if the slot allocation state of another cell changes, IHO will be performed based on the contents of the priority table that does not reflect the current line quality.
[0254]
On the other hand, by performing the IHO at a fixed frame cycle, the contents of the priority table can be updated at any time, so that the above problem can be solved.
[0255]
At the timing specified by the timing control circuit 1803, the slot selection circuit 1804 determines whether or not to move in the IHO based on the priority function and the code multiplex number recorded in the uplink priority table 1801 or the downlink priority table 1802. (Hereinafter referred to as “movement target channel”) and a search target slot.
[0256]
As a method of selecting a movement target channel, a method of selecting the channel of a slot to which only one channel of one code is allocated based on the number of multiplexed codes, or a channel allocated to a slot having the lowest priority function value Is available. As a method of selecting a search target slot, there is a method of selecting a slot in descending order of the priority function value, a method of selecting a slot in descending order of the number of multiplexed codes, and the like.
[0257]
The IHO execution circuit 1805 performs a channel search for the search target slot at the timing specified by the timing control circuit 1803, and performs the IHO so as to maintain the code pooling state.
[0258]
Next, the channel search in the IHO of the IHO execution circuit 1805 will be described.
[0259]
When performing an uplink channel search, interference power measurement circuit 1008 of base station apparatus 1800 measures the received interference power of the search target slot, and outputs the measurement result to IHO execution circuit 1805. On the other hand, when a downlink channel search is performed, communication terminal apparatus 1200 measures the reception interference power of the search target slot, and transmits the measurement result to base station apparatus 1800 as interference power information. Then, demultiplexing circuit 1007 of base station apparatus 1800 outputs the received interference power information to IHO execution circuit 1805.
[0260]
Then, the IHO execution circuit 1805 determines the magnitude relationship between the reception interference power of the search target slot and the threshold, and determines the slot as the handover destination slot when the reception interference power of the search target slot is equal to or smaller than the threshold. On the other hand, when the reception interference power of the search target slot is larger than the threshold, the slot selection circuit 1804 is requested for the next search target slot.
[0261]
Next, the IHO performed by the IHO execution circuit 1805 will be specifically described with reference to FIG. 23 which shows an example of a code multiplexing situation in each slot. In FIGS. 23A and 23B, the horizontal axis represents time slots, and the vertical axis represents multiplexed channels.
[0262]
An upward arrow indicates an uplink and a downward arrow indicates a downlink. That is, in FIG. 23A, downlink channels are assigned to slots # 0, # 2 to # 6, # 8 to # 11, # 13, and # 14, and slots # 1, # 7, and # 12 are assigned to slots. Uplink channels have been assigned. The channel 301 in slot # 8 indicates a multi-code transmission channel used by one user using a plurality of codes.
[0263]
It is assumed that the downlink IHO is performed from the state shown in FIG. 23A, and that the slot selection circuit 1804 selects the channel 302 of the slot # 2 as the movement target channel and the slot # 0 as the search target slot. .
[0264]
In this case, the IHO execution circuit 1805 performs a channel search for the slot # 0, and moves the channel 302 to the slot # 0 if it determines that there is a free slot # 0.
[0265]
FIG. 23B is a diagram showing a code multiplexing state after the channel 302 is moved to the slot # 0 from the state of FIG. As shown in FIG. 23 (b), a channel is not assigned to slot # 2 at all by IHO.
[0266]
Therefore, in this case, for slot # 2, an uplink channel can be allocated, or a multi-code transmission channel such as channel 301 can be allocated, and a large number of slots can be occupied with a small number of code multiplexes. In the case of 23 (a), the channel utilization effect can be improved.
[0267]
Next, the IHO procedure performed by the IHO execution circuit 1805 will be described with reference to the flowchart of FIG.
[0268]
If it is time to execute the IHO in ST2001, information indicating the movement target channel and the search target slot is input from the slot selection circuit 1804 in ST2002.
[0269]
Then, in ST2003, the content of the information input from slot selection circuit 1804 is determined, and if there is no movement target channel, the process ends without performing the following processing. On the other hand, if there is a movement target channel in ST2003, channel search is performed for the search target slot in ST2004.
[0270]
In ST2005, it is determined whether or not there is a handover destination slot from the result of the channel search. If no handover destination slot exists, the process ends without performing the following processing. On the other hand, if there is a handover destination slot in ST2005, the mobile station moves the target channel to the handover destination slot in ST2006.
[0271]
Further, in ST2007, channel assignment information indicating the handover destination slot is output to multiplexing circuit 201 or transmitting / receiving circuit 204.
[0272]
Then, in ST2008, when the process of IHO is to be continued for another channel, the steps from ST2004 to ST2007 are repeated.
[0273]
As described above, the code multiplexing status in each slot is monitored at a predetermined timing, and the IHO is performed based on the priority function value or the like, thereby maintaining the code pooling state and improving the channel utilization effect. . When the channel segregation method is ARP (Autonomous Reuse Partitioning), the effect of reconfiguring reuse partitioning is obtained.
[0274]
In each of the above embodiments, a case has been described where the base station apparatus independently owns the uplink priority table and the downlink priority table, but the present invention is not limited to this. In the case where assignment is made in pairs, etc., the base station device only needs to have one of the line priority tables.
[0275]
Further, in each of the above embodiments, the case where the base station apparatus performs the priority table update processing has been described. However, the priority table update processing may be performed by, for example, a radio network controller (RNC).
[0276]
As is apparent from the above description, according to the present invention, by preferentially searching for a slot where a call has ended in channel allocation, channel segregation can be promoted and efficient channel allocation can be performed. Further, since the contents of the priority table can be updated at any time at a predetermined timing, the base station apparatus can perform channel allocation based on the contents of the priority table reflecting the current channel quality.
[0277]
【The invention's effect】
As described above, according to the present invention, an efficient channel search is performed by preferentially searching for a channel where a call has been terminated, and a timing after a certain period elapses or when a call is terminated. By updating the priority table even at times other than when channel allocation is performed, channel segregation can be promoted and efficient channel search can be performed, based on the contents of the priority table reflecting the current line quality. Channel assignment.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a communication terminal device serving as a communication partner of a base station device according to Embodiment 1 of the present invention.
FIG. 2 is a block diagram showing a configuration of a base station apparatus according to Embodiment 1 of the present invention.
FIG. 3 is a diagram showing an example of an internal configuration of a priority table in the base station apparatus according to Embodiment 1 of the present invention.
FIG. 4 is a flowchart showing an example of a channel assignment method according to Embodiment 1 of the present invention;
FIG. 5 is a diagram showing an example of an internal configuration of a priority table in a base station apparatus according to Embodiment 2 of the present invention.
FIG. 6 is a block diagram showing a configuration of a base station apparatus according to Embodiment 3 of the present invention.
FIG. 7 is a flowchart showing channel assignment processing according to Embodiment 3 of the present invention.
FIG. 8 is a flowchart showing uplink channel assignment processing according to Embodiment 3 of the present invention.
FIG. 9 is a flowchart showing downlink channel assignment processing according to Embodiment 3 of the present invention.
FIG. 10 is a flowchart showing a process of updating a channel assignment priority function at the time of handover according to Embodiment 3 of the present invention.
FIG. 11 is a block diagram showing a configuration of a communication terminal apparatus serving as a communication partner of the base station apparatus according to Embodiment 4 of the present invention.
FIG. 12 is a block diagram showing a configuration of a base station apparatus according to Embodiment 4 of the present invention.
FIG. 13 is a flowchart showing a procedure of a priority table update process according to the fourth embodiment of the present invention.
FIG. 14 is a flowchart showing a procedure of a priority table update process according to the fifth embodiment of the present invention.
FIG. 15 is a block diagram showing a configuration of a base station apparatus according to Embodiment 6 of the present invention.
FIG. 16 shows an internal configuration of an uplink priority table according to Embodiment 6 of the present invention.
FIG. 17 is a flowchart showing an uplink channel allocation method in the base station apparatus according to Embodiment 6 of the present invention.
FIG. 18 is a block diagram showing a configuration of a base station apparatus according to Embodiment 7 of the present invention.
FIG. 19 shows an internal configuration of an uplink priority table according to Embodiment 7 of the present invention.
FIG. 20 is a flowchart showing an uplink channel assignment method in the base station apparatus according to Embodiment 7 of the present invention.
FIG. 21 is a block diagram showing a configuration of a base station apparatus according to Embodiment 8 of the present invention.
FIG. 22 is a block diagram showing a configuration of a base station apparatus according to Embodiment 9 of the present invention.
FIG. 23 is a diagram showing an example of a code multiplexing situation in each slot.
FIG. 24 is a flowchart showing an IHO procedure in the base station apparatus according to Embodiment 9 of the present invention.
FIG. 25 is a flowchart showing a channel assignment method in a conventional TDMA communication system.
[Explanation of symbols]
200, 400, 1000, 1300, 1500, 1700, 1800 base station apparatus
204, 1007 Separation circuit
205 Propagation path measurement circuit
206, 404, 1013, 1304, 1504 Channel assignment circuit
207 Priority table
208 Table Update Circuit
402, 1009, 1301, 1501, 1801 uplink priority table
403, 1010, 1302, 1502, 1802 Downlink priority table
1003 diffusion circuit
1005 Despreading circuit
1011, 1803 Timing control circuit
1012, 1303, 1503, 1804 Slot selection circuit
1701 Selection order calculation circuit
1805 IHO execution circuit

Claims (20)

Storage means for storing an uplink / downlink priority function for all channels, and channel assignment based on the uplink / downlink priority function, and the same channel priority of the downlink at the time of uplink channel assignment Channel assignment means for updating the function and updating the same channel priority function of the uplink when the downlink channel is assigned, wherein the channel assignment means comprises the same channel of the reverse channel of the channel whose priority function has been increased. A base station apparatus, wherein a priority function is lowered, and a priority function of the same channel on a reverse line of a channel whose priority function is lowered is raised. 2. The base station apparatus according to claim 1, wherein the channel allocating unit sets a priority function of the switched channel to a predetermined value when switching the upper and lower lines of the channel. 3. The base station apparatus according to claim 1, wherein the channel assignment unit updates the priority function based on a magnitude relationship between the desired wave power and the interference wave power. 4. The base station apparatus according to claim 3, wherein the channel allocating unit lowers the priority function when the fluctuation of the desired wave power is small and the interference wave power is increasing. A base station device that performs wireless communication by a CDMA / TDD communication method,
Storage means for storing a priority function of each slot; slot selection means for selecting a slot to be searched based on the priority function of each slot; and a channel based on the channel quality estimation value of the selected slot. Channel allocating means for allocating and updating the priority function, wherein the channel allocating means lowers the priority function of a slot having a code multiplexing number equal to or less than a threshold value, A base station device characterized by increasing a degree function. What is claimed is: 1. A base station apparatus for performing wireless communication by a CDMA / TDD communication method, comprising: storage means for storing a threshold for each transmission rate and a priority function of each slot for each transmission rate; Slot selection means for selecting a search target slot in descending order of the priority function, and when the received interference power of the selected slot is equal to or less than the transmission rate threshold value of the connection-requested call, a channel is assigned to the slot. A base station apparatus comprising: channel assignment means for assigning. 7. The base station apparatus according to claim 6 , wherein the channel allocating unit increases a priority function of the slot to which the channel is allocated. 8. The base station apparatus according to claim 6 , wherein the channel allocating unit reduces the priority function of the slot when the received interference power of the search target slot is larger than a threshold. What is claimed is: 1. A base station apparatus for performing wireless communication by a CDMA / TDD communication method, comprising: storage means for storing a priority function of each slot and a code multiplexing number; and a code in a selection candidate slot not yet selected as a search target. Slot selection means for selecting a slot to be searched from among those having the largest number of multiplexes, and channel allocation means for allocating a channel to the slot when the reception interference power of the selected slot is equal to or less than a threshold. Characteristic base station device. The base station apparatus according to claim 9 , wherein the slot selecting means selects a slot having the highest priority function among selection candidate slots having the largest number of code multiplexes as a search target. A base station apparatus for performing wireless communication by a CDMA / TDD communication method, comprising: a storage unit for storing a priority function and a code multiplex number of each slot; Selection rank calculating means for calculating a selection rank function as a variable; slot selection means for selecting, as a search target, a slot having the highest selection rank function among slots not yet selected as a search target; And a channel allocating means for allocating a channel to the slot when the received interference power is equal to or less than a threshold. Selection order calculation means, the selection order function of each slot, according to claim 11, characterized in that calculated by adding the number of code multiplexing priority function such a value obtained by multiplying a weighting factor into the slot of the slot Base station device. 13. The base station apparatus according to claim 9 , wherein the channel allocating unit allocates a channel to the slot when the received interference power of the searched slot is equal to or less than a threshold. 14. The base station apparatus according to claim 9 , wherein the channel assignment unit increases a priority function of a slot to which a channel is assigned. The base station according to any one of claims 9 to 14 , wherein the channel allocating unit reduces the priority function of the slot when the received interference power of the searched slot is larger than a threshold. apparatus. A channel assignment method characterized by individually controlling uplink / downlink priority functions for all channels and decreasing the priority function of the same channel on the reverse link of the channel whose priority function has been increased. A channel assignment method characterized by individually controlling uplink / downlink priority functions for all channels and increasing the priority function of the same channel on the reverse link of the channel whose priority function has been lowered. 18. The channel assignment method according to claim 16 , wherein when switching the upper and lower lines of the channel, the priority function of the switched channel is set to a predetermined value. In the wireless communication of the CDMA / TDD communication method, the search target slots are selected in descending order of the priority function of the transmission rate of the call for which the connection request has been made, and the reception interference power of the selected slot indicates the call for which the connection request was made A channel is allocated to the slot when the transmission rate is equal to or less than the threshold of the transmission rate. In wireless communication of the CDMA / TDD communication method, a slot to be searched is selected from among slots having the largest number of code multiplexes among selection candidate slots not yet selected as a search target, and reception interference power of the selected slot is reduced. A channel assignment method, wherein a channel is assigned to the slot when the value is equal to or less than a threshold value.

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